Sequence analysis of ITS-rDNA from 70 natural isolates of Naegleria (Table 1) was performed to gain insight into the genetic relationships among strains and species. A phylogenetic tree based on the NJ method is presented in Figure 1, and corroborates previous finding of six main clusters of Naegleria isolates 12. Most clusters appear monophyletic with high bootstrap and Bayesian supports, and Cluster 5 is the most prominent with 30 annotated Naegleria isolates (Figure 1). A closer inspection of the SSU rRNA identified intron sequences inserted at position S516 in 21 of 70 strains analyzed. All introns, except one 8, belong to the highly complex twin-ribozyme group I intron family 719. Group I introns at position 516 in SSU rDNA are relatively common among eukaryotic microorganisms 19. Interestingly, the Naegleria 516 introns (Nae.S516; for intron nomenclature see 32), show a widespread but scattered distribution among the Naegleria isolates (Figure 1). All clusters, except the early diverging Cluster 6 2, harbor isolates that carry the group I intron. Furthermore, no linkages could be noted between the presence of the S516 intron and environmental factors such as optimal growth temperature, pathogenesis, habitats, and geographical origin of Naegleria isolates.

Fourteen of the 21 introns were selected for more detail structural characterizations (see Table 1). All introns, but one (N. byersi NG597), possess the twin-ribozyme group I intron organization previously reported 716, and an updated RNA consensus structure diagram is shown in Figure 2. The intron consists of three functional domains, identified as distinct intron structures. The autocatalytic Naegleria splicing ribozyme (NaGIR2) is responsible for intron excision and exon ligation during precursor rRNA processing in the Naegleria nucleolus, as well as for the generation of circular intron RNAs 728. NaGIR2 represents a typical group IC1 intron with clear structural resemblance to the well-studied Tetrahymena ribozyme 1415. The consensus structure (Figure 2) is strongly supported by compensatory base substitutions among the Naegleria introns. The most prominent differences between the Naegleria and Tetrahymena ribozymes are the lack of a P9.2 segment in Naegleria, the presence of an optional tetra-loop in L5b, and a large sequence insertion (approximately 950 nt) in P6b harboring the homing endonuclease gene (NaHEG) and the capping ribozyme NaGIR1 (Figure 2).

NaGIR1 is a group I-like ribozyme with an evolved biological role in intron NaHEG expression 2930, likely to generate a lariat cap-structure at the 5' end of the Naegleria homing endonuclease messenger 30. The three-dimensional architecture of NaGIR1 is related to that of bacterial tRNA group I intron ribozymes 182933, but with a unique catalytic core organization that contains the novel pseudoknot segment P15 7293134. As seen from Figure 2, most of the core nucleotides are highly conserved among the various Naegleria capping ribozymes. Variable regions are almost exclusively located in the terminal loops of P6 and P8, the internal loop junction J5/4, and sequences flanking NaGIR1 and NaHEG.

The third intron domain consists of the NaHEG which codes for a 245 amino acid (aa) His-Cys endonuclease that recognizes and cleaves the intron lacking allele sequence in rDNA 2425. An alignment of the derived amino acid sequence from the studied Naegleria introns is presented in Figure 3. The amino acid identities between pairs vary from 81 % to 100 %, with the positive charged N-terminal region (first approximately 80 aa) as the most variable part. The N-terminal region contain arginine and lysine rich sequences that resembles known RNA binding domains 3536, indicating that the NaHEG encodes a complex protein with both endonuclease and RNA binding functions. All three intron domains at the RNA-level (NaGIR1, NaGIR2, endonuclease mRNA) are possible targets for intron protein RNA binding. Both NaGIR1 and NaGIR2 are known to fold correctly and to be catalytically active in vitro without assistance of proteins 73134, suggesting no essential maturase function of the intron encoded protein. However, the intron protein could still be able to bind to it own messenger, which is predicted to be highly structured 7. This possibility remains to be further experimentally explored. Residues previously noted to be essential for endonuclease active site definition, catalysis, and zinc coordination (Figure 3) 25 are highly conserved. The non-synonymous to synonymous substitution rates (dN/dS) were calculated for the NaHEG sequences and found in all cases to be below one (data not shown), indicating purifying selection. Interestingly, the intron present in N. martinezi NG872 isolate contains hallmarks of a degenerated NaHEG, seen as multiple frame shifts and small indels (Figure 3).

NaGIR2 represents the splicing-ribozyme domain of Nae.S516 and thus corresponds to the sequences present in a prototype group I intron such as the Tetrahymena intron. We have previously performed phylogenetic analysis of various nuclear S516 group I introns, including five NaGIR2 variants, and recognized the Naegleria introns as a monophyletic clade among the group IC1 introns 16. Here we extend the analysis to include 14 NaGIR2 variants representing the different isolates of Naegleria. Furthermore, we also include a host rDNA analysis based on their corresponding ITS-rDNA sequences. The intron phylogeny was based on 356 sequence positions within NaGIR2, strictly aligned according to the structure diagram in Figure 2. Different methods (NJ, MP, ML, and BAY) were used to build the phylogenetic trees, and all trees were essentially identically in topology. Similarly, the ITS-rDNA phylogeny was based on 415 sequence positions using the same set of tree building methods described above in intron analysis. Figure 4 shows representative NJ trees of both the ITS-rDNA and NaGIR2 phylogenies with overall congruent branching patterns and significant bootstrap and Bayesian supports. The only exception is N. italica AB-TF-3 (Figure 4), that could represent a recent horizontal intron transfer. However, the N. italica ITS-rDNA branch topology is only poorly supported in NJ analysis (77 %) and without bootstrap and Bayesian supports in the MP, ML, and BAY analyses, respectively. Thus, we infer there are no experimental support of horizontal intron transfer and conclude that the NaGIR2 domain, representing the Nae.S516 intron, is vertically inherited within the Naegleria genus.

Divergent evolutionary histories of group I splicing ribozymes and their HEGs have been described in several nuclear group I introns 373839. The Naegleria twin-ribozyme intron is highly unusual among group I introns in that it contains two distinct structural domains (NaGIR1 and NaHEG) inserted into the same peripheral region (P6) of NaGIR2 (see Figure 2). To address the relationships among the variants of NaGIR1 and NaHEG, as well as between the different intron domains (NaGIR1, NaGIR2, and NaHEG) we performed phylogenetic analyses based on the sequence alignments. Figure 5 presents representative NJ trees of NaGIR1 and NaHEG. The phylogenetic trees, built by the MP, ML, and BAY methods, were essentially identical. The NaHEG tree was based on 747 aligned positions and possesses significant bootstrap and Bayesian supports. The total size of the NaGIR1 domain is less than 250 nucleotides in size and thus only 230 positions could be included in the analysis. However, we found the tree topology to be well supported in bootstrap and posterior probability analyses. Interestingly, the NaGIR1, NaHEG, and NaGIR2 (compare Figures 4 and 5) phylogenies were found to have congruent branching topologies consistent with a co-evolutionary pattern of the domains within introns. But there is one clear exception in N. carteri NG055 (see Figure 5), suggesting a homologous recombination-like event between natural sequence intron variants.

A Naegleria S516 group I intron with only NaHEG or only NaGIR1 insertions has never been observed, suggesting a strong linkage between the domains. Both structural and functional data give further support to a close linkage between the NaGIR1 and NaHEG domains. Jabri and Cech 34 showed that the RNA structure essential for NaGIR1 catalysis includes nucleotide residues within the NaHEG coding region. Functional experiments in yeast conclude that expression of NaHEG, and subsequent endonuclease activity in yeast extracts, is completely dependent on a functional NaGIR1 ribozyme 28. Thus, the NaGIR1 and NaHEG domains have to be considered as one functional unit within the Nae.S516 intron.

One of the best-studied tetraloop receptor interaction is the L5b-P6a tertiary structure in the Tetrahymena group I intron ribozyme 40. Here, the GAAA loop in L5b specifically binds to the 11-nt receptor motif CCUAAG-UAUGG within the helical stem of P6a by docking into the shallow groove. The L5b-P6a interaction in Tetrahymena is essential for an efficient folding of the P4–P6 domain, and subsequently the folding and activity of the splicing ribozyme.

Two of the most variable parts in the Naegleria GIR2 splicing ribozyme are L5b and P6a (Figure 2). A closer inspection of the 13 twin-ribozyme intron sequences identify tetra-, penta-, and hexaloops in L5b of 8, 4, and 1 introns, respectively. All tetraloops belong to the GNRA family (N = A, G, C or U; R = A or G) known to specifically interact with receptor sequences. To address the distribution pattern of the L5b tetraloops among the various Naegleria intron isolates a phylogenetic analysis based on 1370 positions, representing the complete twin-ribozyme introns, was performed. Essential identical trees were obtained from the NJ and MP methods, and a representative NJ tree is shown in Figure 6A. Interestingly, introns harboring a L5b GNRA tetraloop cluster together with high bootstrap support, suggesting that a L5b tetraloop was gained late the evolution of the Naegleria genus. The only exception appears the L5b pentaloop of the N. philippinensis RJTM intron (Figure 6A), but this example may represent a secondary loss of a GNRA tetra-loop (e.g. GUAA to AUAAA).

The primary function of GNRA tetraloops is to participate in long-range RNA-RNA interactions by specific binding to a receptor motif. A variety of receptor motifs, ranging from 4 to 12 nt, have been recognized experimentally 414243. Figure 6B presents secondary structure diagrams of the various NaGIR2 P6a regions and their corresponding L5b loops. A prominent difference in the P6a structure is noted among introns possessing L5b GNRA tetraloops compared to those with penta- or hexaloops. Introns with GNRA loops contain a less tightly base-paired P6a stem with several proposed exposed residues (see Figure 6B) compared to the P5b penta- or hexaloop containing introns (compare N. clarki RU30 and N. carteri NG055). We speculate that the exposed residues in P6a could be involved in RNA-RNA interactions as GNRA receptors. However, these sequences do not fit any known consensus motifs, suggesting that new motifs are yet to be experimentally identified.

The following Naegleria isolates were DNA sequenced at ITS-rDNA and Nae.S516 intron regions in this study: N. clarki RU30 (ITS-rDNA and Nae.S516); N. clarki RU42 (ITS-rDNA and Nae.S516); N. pringsheimi 1D (ITS-rDNA and Nae.S516); N. philippinensis RJTM (ITS-rDNA and Nae.S516); N. carteri NG055 (ITS-rDNA and Nae.S516); Naegleria sp. NG647 (ITS-rDNA and Nae.S516); Naegleria sp. NG358 (ITS-rDNA and Nae.S516); Naegleria sp. NG393 (ITS-rDNA and Nae.S516); Naegleria sp. NG498 (ITS-rDNA and Nae.S516); Naegleria sp. NG169 (ITS-rDNA);Naegleria sp. NG336 (ITS-rDNA); Naegleria sp. NG491 (ITS-rDNA); Naegleria sp. NG492 (ITS-rDNA). The strains without designation are under revision and will be proposed proper species names based on phylogenetic analyses of ITS1-5.8S-ITS2 sequences (De Jonckheere et al. in preparation). A complete list of all 70 Naegleria isolates included in this study is presented in Table 1. DNA samples of Naegleria strains were prepared as described previously 2, dissolved in water, and applied as template in 50 μl standard PCR reactions. Amplified product of interest were plasmid cloned into the pGEM^®-T Easy Vector System I (Promega). Individual clones where DNA purified and sequenced with the ABI PRISM BigDyeTerminator Cycle Sequencing Ready Reaction Kit (Perkin-Elmer), running on an ABI Prism 377 system (Perkin-Elmer), or using the sequencing service from MWG Biotech 48. Two or more individual clones were sequenced from all introns and ITS-rDNA regions analysed. The following oligoprimers were used in Nae.S516 PCR amplifications and DNA sequencing analyses: OP 25 (5'-CTC GAA TTC GCT CTT GGA GCT GGA ATT A-3'), OP 26 (5'-ACG AAG CTT ATT TCT AAG CCT-3'), OP 28 (5'-CAG AGG AGT TTC TTA CCT ATC-3'), OP 131 (5'-AAA CGA ATT CTA TTG ATT AGT AGT-3'), OP 946 (5'-GAA TTG AAA AAG CTT GAT-3'), OP 1200 (5'-AAA CAA ATG CTA TTG ATC A-3'), OP 1201 (5'-GAA CGT CTA GAG ACT ACA CGG-3'), OP 1042 (5'-CGA TTT TCC ATG ATT TGG G-3'), OP 1043 (5'-ATA CCT CAA CAG AGG TCC-3'), OP 1044 (5'-GGA CGT CTA GAG ACT ACA CGG-3'), OP 1045 (5'-TGA TGC ACG TAC GAA TCG GAG C-3'), OP 276 (5'-GGT AAA CAA ATC CCT GTT-3'), OP 823 (5'-TAA CCA TTT TGT ATG GGA-3'). Heteroplasmic rDNA alleles (intron-containing/intron lacing) were not observed. The following oligoprimers were used in ITS-rDNA PCR amplifications and DNA sequencing analyses: OP 918 (5'-AAC CTG CGT AGG GAT CAT TT-3'), OP 919 (5'-TTT CCT CCC CTT ATT AAT AT-3').

Multiple alignment of sequences were performed by using Megalign (Version 5.06) included in the Lasergene package from DNASTAR, Inc 49, Bioedit (Version 7.0.4.1; 50), manuel refinements. Phylogenetic analyses and non-synonymous to synonymous substitution rates 51 were conducted using MEGA version 2.1 52, PAUP* (Version 4.0 Beta) 53, and MrBayes (version 3.1) 5455. Trees were built with the methods of neighbor-joining (NJ) using different distance matrixes, maximum parsimony (MP) with the branch and bound search method, as well as Bayesian analyses (BAY) and maximum likelihood (ML) using different evolutionary models. The reliabilities of the tree topologies were evaluated by bootstrapping (NJ, MP, and ML), and posterior probability (BAY).

Two different data sets of the internal transcribed rDNA spacer region (ITS-rDNA: ITS1-5.8S-ITS2) were used. In analysis with all the 70 Naegleria isolates, only 287 nucleotide positions could unambiguously be aligned due to high sequence variation in ITS2. However, when the analysis was restricted to the 14 intron-containing Naegleria isolates we extended the ITS-rDNA region to 415 nucleotide positions. Based on the multiple sequence alignment a NJ tree was constructed with the Kimura-2 evolutionary model of substitution (K2), with pair wise deletion of gaps and bootstrapped with 2000 replications with a cut-off value of 50%. Similarly, intron trees are constructed with NJ-K2 parameters. The robustness of the tree topologies were tested by the NJ-K2 parameter (first value), MP branch and bound search criteria (second value), and ML with the HKY+G model of substitution selected by Modeltest 3.7 56, all from 1000 replicates. The last values where constructed by running 1000000 generations of Metropolis-coupled Markov chain Monte Carlo, and trees were sampled every 100 generations (average standard deviation of split frequencies below 0.01). A consensus tree was generated from the 75% last trees to find posterior probabilities (Burn-in value = 2500).